SU1158823A2 - Device for diverting flue gases - Google Patents

Abstract

l .. DEVICE FOR DISPOSAL OF BOTTOM GASES auth. No. 1073533, characterized in that, in order to reduce the concentration of harmful impurities on the ground by increasing the flue gas emission height, the nozzle outlet is located under the nozzle outlet nozzle

Description

1 The invention relates to energy and can be used in devices for removal of flue gases from heat and power equipment According to the main author. No. 1073533, a device for flue gas removal is known, which contains a dyma pipe with a receiver and an oval section attached thereto with a nozzle connected to a secondary body source. The nozzle is located in front of the nozzle with respect to the direction of the velocity vector of the atmospheric masses, and the ratio of the nas axes is five. The oval shape of the nozzle allows a substantial increase in the flue gas emission height. With an optimal value of the ratio of the oval axes equal to five, the increase in the ejection is 17%. The feeding of the black nozzle of an additional working fluid has a greater effect on the efficiency of dispersion. However, the supply of an additional body leads to an increase in the experimental costs of the device by m, the value of which substantially depends on the size and location of the nozzle and may be unacceptably large. The purpose of the invention is to reduce the concentration of harmful impurities at the sites of TIR by increasing the height of the flue gas emission. This goal is achieved by the fact that in the flue gas removal device the nozzle outlet is located under the nozzle outlet nozzle (0.05-0.1) d5, where dg is the equivalent diameter of the nozzle outlet nozzle ,. СЗ - {N 1Г where F is the nozzle outlet area. In addition, in order to reduce operating costs, the diameter from the versatility of the nozzle is 0.3. FIG. I shows a device for the removal of flue gases, a general view of IL 4IG. 2 - nozzle section and nozzle. The device contains a chimney 1 and nozzles 2 with a nozzle 3. Coaxially the pipe 1 is installed receiver 4 can be rotated on the support 5, the inlet of which is aligned with the outlet of the pipe 1. 32. The receiver 4 is rotated by the actuator 6 by the controller 7, signals that come from the goniometric pneumatic tubes 8. To eliminate the flow of flue gases through the support 5, the device has a labyrinth seal 9. The nozzle 3 is connected to a source of additional working fluid made in the form The nozzle 10, the suction nozzle of which is connected by a pipe 11 with an air inlet 12 and a gas collector 13, equipped with remote control throttle valves 14. The device works as follows. Combustion products are transported through chimney I to receiver 4 and then through nozzles 2 are released into the atmosphere. Stream of flue hectares: 3 in the mouth has an oval shape, which leads to an increase in the removal of flue gases. To ensure the efficiency of the device in operation, the large axis of the cross section of the nozzle 2 is oriented in the direction of the velocity vector of atmospheric masses. The orientation is carried out by the actuator 6 at the command of the regulator 7. To change the height of the flue gases from the blower 10, an additional working fluid is supplied through the nozzle 3, for which flue gases, air or a mixture are used. The parameters of the working fluid are changed by throttle valves. The outlet of the nozzle 3 is located below the outlet of the nozzle 2 by the value (0.05-0, I) d3. In this case, the jet of additional working medium expands somewhat, which leads to an increase in the determining jet size in the cross section of the outflow of the jet of flue gases, as a consequence, to a decrease in the active influence of the flow of atmospheric masses on the jet of flue gases due to a decrease in the aerodynamic drag force. The increase in flue gas emissions due to the supply of additional working fluid with a change in the diameter of the nozzle outlet orifice changes significantly. Here, the optimum diameter values from the minimum operating cost condition are achieved at (0.3) da. . Based on the experimental studies carried out on the models of the proposed device and the prototype in the laboratory of gas dynamics of the Kazan branch of MEI, the following results were obtained. When the nozzle outlet is located below the nozzle outlet by an amount equal to (0.050, 1) 1e, which is dl, 2d3 on the order of 5%, for d.0.3d3 - 4%. Both an increase and a decrease in displacement from the specified range (0.050, 1) dj leads to a reduction in the influence of the supply of an additional body on the height of the flue gas emission. At 0, ld, the value of 5-. Decreases in the injection section of the jets, as a result, the discharge height decreases (- displacement of the nozzle orifices and nozzle, - hydrodynamic parameter: the ratio of velocity pressures ctpyH of the additional working fluid and a stream of flue gases). At, 05 d the force of the aerodynamic pressure of the wind flow directly on the flue gas stream increases and the rise decreases. With, 3 d operating costs are minimal. Compared to df.0,6 d, they decrease, for example, by 1.8-2 times. The effectiveness of the invention increases with short-term connections to the chimney of equipment emitting flue gases with a high content of harmful impurities. The use of the proposed device allows to significantly increase the flue gas emission height and, as a result, to reduce the concentration of harmful impurities in the field, as well as reduce operating costs for efficient dispersion. Compared with the base object, in which a single barrel can be a smoke pipe with a cylindrical exit part, the dispersion efficiency in adverse weather conditions significantly increases.

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Claims (2)

1 .. DEVICE FOR DRAINING OF SMOKE GASES by ed. No. 1073533, characterized in that, in order to reduce the concentration of harmful impurities in the area by increasing the height of the flue gas emission, the nozzle outlet is located under the nozzle outlet at a distance from it equal to (0.05-0.1) d _d , where is the equivalent diameter of the nozzle outlet, where F is the area of the nozzle outlet. 2. The device according to π. 1, characterized in that, in order to reduce operating costs, the diameter of the nozzle opening is 0.3 d ^. ... SUn, 1158823 2.